DE102014104017A1 - Electrochemical device - Google Patents

Abstract

An electrochemical device comprising a stack of a plurality of electrochemical units successive along a stacking direction, each comprising an electrochemically active membrane-electrode assembly, a bipolar plate and at least one sealing element, at least one medium channel extending along the stacking direction through a plurality of the electrochemical Units therethrough, at least one flow field through which a medium from the medium channel can flow transversely to the stacking direction of the medium channel to another medium channel, and at least one connecting channel through which the flow field and the medium channel are in fluid communication with each other, which an overlapping of successive in the stacking direction sealing elements in the region of a connecting channel allows and no complex design solution for supporting or reinforcing the sealing element requires, it is proposed that the Di The invention relates to a connecting channel region in which the sealing arrangement traverses the at least one connecting channel and at least one adjacent region in the longitudinal direction of the sealing arrangement in front of or behind the connecting channel region, wherein the sealing arrangement has a smaller average height in the connecting channel region than in FIG the neighboring area.

Description

The present invention relates to an electrochemical device comprising:
a stack of a plurality of electrochemical units following one another in a stacking direction, each comprising an electrochemically active membrane electrode assembly, a bipolar plate and at least one sealing element,
at least one medium channel extending through a plurality of the electrochemical units along the stacking direction,
at least one flow field through which a medium from the medium channel can flow transversely to the stacking direction from the medium channel to another medium channel, and
at least one connecting channel through which the flow field and the medium channel are in fluid communication with each other.

In known electrochemical devices of this kind, the space of the electrochemical device through which a medium, for example a fuel gas, an oxidant or a coolant flows, is filled with spaces which are filled with another fluid medium during operation of the electrochemical device or with respect to an external space of the electrochemical device Device sealed by sealing elements, which are designed over its entire sealing length with a substantially unchanged cross-section.

In the region of the connecting channels between the medium channels and the flow fields of the electrochemical device, the sealing elements are usually arranged offset from one another in a direction perpendicular to the stacking direction when metallic bipolar plates are used, that is to say the sealing elements do not rest on the entire sealing length - as seen in the stacking direction. congruent. This offset of the sealing elements makes it difficult to distribute the sealing loads evenly. Furthermore, due to the patchwise offset between the sealing elements, the use of a marginal or reinforcing foil at the edge of the electrochemically active membrane-electrode assembly is required because the staggered sealing elements are not suitable for defining an edge of the electrochemically active region. Such an edge or reinforcing film must be applied in an additional process step.

In another known embodiment, the sealing element on the side of the bipolar plate, on which a connecting channel between the medium channel and a flow field is arranged, guided around the medium channel, and a sealing element separating the medium channel from a flow field is arranged only on the other side of the bipolar plate , In this case, however, a support or reinforcement of the sealing element is required, to which there is no counterpart on the other side of the bipolar plate, which requires more complex constructive solutions. Furthermore, even in this known embodiment, the sealing lines of successive in the stacking direction sealing elements no longer completely overlap each other.

The present invention has for its object to provide an electrochemical device of the aforementioned type, which allows overlapping of successive in the stacking direction sealing elements in the region of a connecting channel and no complex design solution for supporting or reinforcing the sealing element requires.

According to the invention, this object is achieved by an electrochemical device according to claim 1, in which the sealing arrangement comprises a connecting channel region in which the sealing arrangement traverses the at least one connecting channel and at least one adjacent region lying in front of or behind the connecting channel region in the longitudinal direction of the sealing arrangement wherein the sealing arrangement, in particular at least one sealing element of the sealing arrangement, in the connecting channel region has a lower average height than in the neighboring region.

The invention is thus based on the concept of providing a height-adjusted or height-profiled sealing arrangement, in particular with at least one height-adjusted or height-profiled sealing element in the area of media supply and / or media removal between a medium channel and a flow field associated with the medium channel.

In particular, the connection channel may be delimited by two parts or layers of a bipolar plate which touch one another in an edge region which surrounds the flow field and the medium channel.

In this case, the parts or layers of the bipolar plate can be welded or glued together, for example, or joined together in a different manner in a sealing manner.

In the region of the connection channel, the two parts or layers of the bipolar plate are spaced apart to provide fluid communication between the medium channel and the associated flow field.

An area of a part or a position of a bipolar plate, which is offset from the other part or the other position of the bipolar plate along the stacking direction in order to form the connecting channel, is referred to below as an elevation.

The differences in height between the elevation and the adjacent regions of the part or the position of the bipolar plate are so small in the region of the connection channel that the sealing element still has the necessary degree of displacement, as is to be expected in an assembly process of the electrochemical device is compressed in order to seal reliably, on the other hand, but also not compressed so much that the bipolar plate or the sealing element are damaged.

It can be assumed that a sealing element with a desired sealing gap height in the range of a few tenths of a millimeter to about one millimeter still works reliably even with a maximum deviation of the gap of about 0.05 mm to about 0.2 mm the exact value of the permitted deviation depends on the gap dimensions and the sealing materials.

If the slopes in the flanks of the elevations are at most 45 °, the allowable deviation of the gap dimension at an assembling accuracy when stacking the components of the electrochemical device of a few tenths of a millimeter is not exceeded.

Preferably, the slopes in the flanks of the elevations are in the range of less than 30 °, in particular in the range of less than 20 °.

In the electrochemical device according to the invention, a closed sealing line surrounding the flow field can be guided via the connecting channel, and the sealing elements succeeding one another in the stacking direction can be arranged substantially overlapping over their entire sealing length.

The increase in the bipolar plate in the region of the connecting channel can be stabilized by the structural design of the bipolar plate.

In particular, it may be provided that the bipolar plate is designed with respect to the material used and the design of the increase so that the bipolar plate has sufficient inherent stability in the region of the increase, so that the connecting channel remains open against each other even during clamping of the successive in the stacking direction electrochemical units ,

Alternatively or additionally, it may be provided that the bipolar plate has support regions and / or support elements in the region of the connection channel, which stabilize the increase mechanically.

Alternatively or additionally, it may be provided that a stabilizing element is arranged between the bipolar plates in the region of the connecting channel in order to support the raising of at least one bipolar plate.

Such a stabilizing element may be manufactured as a separate element from the bipolar plates and inserted between the bipolar plates.

Alternatively, it can also be provided that the stabilizing element is formed integrally with one of the bipolar plates and is introduced by a folding process in the space between the bipolar plates.

The sealing surface on which the sealing element rests against a bipolar plate in the region of the connecting channel can be substantially planar.

But it is also possible that this sealing surface has structures. For example, it could be provided that the sealing surface is corrugated.

If the height h (that is, the extent along the stacking direction) of the sealing assembly in the assembled channel region or in the adjacent region is the same everywhere in the assembled state of the electrochemical device, then the average height of the seal assembly in the respective region corresponds to this constant Height. On the other hand, if the height h of the seal assembly varies in the final assembled state of the electrochemical device in the connection channel region and / or in the neighboring region, the average height of the seal assembly in the region concerned will be an average obtained by averaging over the length of that region is to be determined away.

In a preferred embodiment of the invention it is provided that a transition region is arranged between the connection channel region and the neighboring region, in which the height of the sealing arrangement decreases starting from the neighboring region to the connection channel region.

The fluid medium may in particular be an oxidizing agent, a fuel gas or a coolant of the electrochemical device.

Preferably, the medium may flow through the flow field substantially perpendicular to the stacking direction of the electrochemical device from the medium channel to another medium channel.

Preferably, at least one sealing element of the sealing arrangement is in contact with the bipolar plate in the connecting channel area and in the adjacent area, wherein the mean distance H of an outer side of the bipolar plate facing this sealing element is greater from a reference plane of the bipolar plate aligned perpendicular to a stacking direction in the connecting channel area as in the neighboring area.

The reference plane may in particular be a central plane of a two-layered bipolar plate, along which the two layers of the bipolar plate abut one another in an edge region of the bipolar plate and / or in the adjacent region of the sealing arrangement.

The sealing element facing the outer side of the bipolar plate is preferably inclined in a arranged between the connecting channel region and the adjacent region transition region relative to the reference plane of the bipolar plate.

In this case, the average angle of inclination of the sealing element facing the outside of the bipolar plate relative to the reference plane in the transition region is at most about 45 °, in particular at most about 30 °, more preferably at most about 20 °.

Furthermore, it is preferably provided that the sum of the mean height h of the sealing arrangement and the mean distances H ₁ , H ₂ of the outer side of the bipolar plate facing away from the reference plane of the bipolar plate from the reference plane in the connection channel region (h _V + H _V1 + H _V2 ) and in the neighboring region (h _N + H _N1 + H _N2 ), particularly preferably also in the transition region (h _U + H _U1 + H _U2 ), is substantially the same size.

In a preferred embodiment of the invention, it is provided that at least one of the electrochemical units comprises a sealing arrangement with two sealing elements which together bridge a distance between the bipolar plate of the relevant electrochemical unit and a Biopolarplatte an adjacent electrochemical unit along the stacking direction.

It can be provided that the sealing elements are designed and arranged such that they - seen along the stacking direction - at least partially overlap each other, preferably over the entire length of the sealing elements away.

It is particularly favorable if the sealing elements are designed and arranged in such a way that one of the sealing elements completely overlaps the other sealing element - seen along the stacking direction - preferably over the entire length of the sealing elements.

In a preferred embodiment of the invention, the bipolar plate comprises two parts or layers, which are at least partially spaced from each other in the connecting channel area.

It can be provided that the average distance H ₁ , H ₂ of the reference plane of the bipolar plate facing away from the bipolar plate of the reference plane of the bipolar plate in both parts or layers of the bipolar plate in the connection channel area is greater than in the neighboring area.

In this case, both parts or layers of the bipolar plate are provided in the region of the connecting channel, each with a lift. These elevations along the stacking direction may have the same height or different heights.

It can further be provided that the mean distance H ₁ , H ₂ of the outside of the bipolar plate remote from the reference plane of the bipolar plate from the reference plane of the bipolar plate is substantially the same in one of the parts or layers of the bipolar plate in the connection channel region as in the neighboring region ,

In this case, only one of the parts or only one of the layers of the bipolar plate is provided with an elevation in the region of the connecting channel.

In order to ensure that the connecting channel remains open against each other even after the electrochemical units of the electrochemical device have been clamped, it can be provided that at least one of the parts or layers of the bipolar plate is provided with one or more support regions with which this part or position of the bipolar plate is supported in the connecting channel area at the other part or at the other position.

The support region may be formed for example in the form of a round or elongated cup or a web.

The support region is preferably substantially completely covered by the sealing element.

The support region is preferably formed integrally with one of the parts or layers to be supported.

In order to ensure that the connecting channel remains open against each other even after the electrochemical units of the electrochemical device have been clamped, it can be provided as an alternative or in addition to such supporting regions that at least one stabilizing element is arranged in the intermediate space between the two parts or layers of the bipolar plate.

Such a stabilizing element can be manufactured separately from the parts or layers of the bipolar plate and inserted into the space between the two parts or layers of the bipolar plate.

Alternatively, it can also be provided that the stabilizing element is formed integrally with one of the parts of the bipolar plate.

In this case, the stabilization element can be introduced in particular by a forming process, for example by a folding operation, in the assembly of the bipolar plate in the space between the two parts or layers of the bipolar plate.

The sealing element can in principle be fixed to any other element of the electrochemical unit comprising the sealing element.

For example, it can be provided that the sealing element is fixed to the bipolar plate.

In a preferred embodiment of the invention, however, it is provided that at least one sealing element of the sealing arrangement is fixed to the membrane-electrolyte arrangement of the respective electrochemical unit.

It is particularly favorable if at least one sealing element is fixed to a gas diffusion layer of the membrane electrolyte arrangement of the respective electrochemical unit.

The sealing element may in particular be injection-molded or adhesively bonded to the membrane-electrolyte arrangement, in particular a gas-diffusion layer of the membrane-electrolyte arrangement.

Preferably, at least one sealing element comprises an elastomeric material. In particular, it can be provided that the sealing element is substantially completely formed from an elastomeric material.

The bipolar plate preferably comprises a metallic material and in particular may be substantially completely formed from a metallic material.

The electrochemically active membrane-electrode assembly preferably comprises a polymer electrolyte membrane (PEM).

The electrochemical device may in particular be designed as a fuel cell stack or an electrolyzer.

In the case of the electrochemical device according to the invention, the height of the sealing element or of the sealing elements of the sealing arrangement in the region of the connecting channel is adapted to the course of the sealing surface of the bipolar plate such that a closed sealing line is achieved around the flow field and / or the medium channel.

In addition, with such a variable-height sealing element or variable-height sealing elements, the flanks of a region of the bipolar plate raised in the area of the connecting channel can also be sealed.

Sealing elements on different sides of a bipolar plate can - seen in the stacking direction - are substantially overlapping, in particular substantially congruent, executed.

Due to the height adjustment of the sealing element or the sealing elements of the seal assembly no offset of the sealing elements perpendicular to the stacking direction is more necessary.

The sealing element of the sealing arrangement can directly surround the electrochemically active membrane-electrode arrangement; in particular, it is no longer necessary to provide the membrane-electrode assembly with an additional reinforcing edge.

Preferably, at least one sealing element is injection-molded onto a gas diffusion layer of the membrane-electrode arrangement. In this case, the height of the sealing profile is adapted to the shape of the raising of a part or a position of the bipolar plate in the region of the connecting channel.

Alternatively or additionally, flat seals of variable height can also be used as sealing elements on one or both sides of a bipolar plate, which preferably cooperate with a sealing projection provided on the bipolar plate, for example in the form of a cutting edge or a compression edge, in order to seal the sealing gap.

The sealing arrangement is preferably designed in two parts, in particular with an anode-side gas diffusion layer as a support for a first sealing element and a cathode-side gas diffusion layer as a support for a second sealing element.

In a preferred embodiment, a bottom part comprises the medium channels, on the edge of which sealing profiles are formed on both sides, and the active surface in which the flow fields are arranged and on the edge of which only part of a sealing profile is arranged on one side. A cover part in this case comprises the second part of the sealing profile, which surrounds a flow field of the bipolar plate and thus forms the second half of the sealing arrangement.

Further features and advantages of the invention are the subject of the following description and the drawings of exemplary embodiments.

In the drawings show:

1 a fragmentary schematic plan view of an electrochemical unit of a plurality along a stacking direction successive electrochemical units comprising electrochemical device in the range of a fuel gas supply and a coolant supply;

2 a schematic section through the fuel gas supply of the electrochemical unit 1 , along the line 2-2 in 1 ;

3 a schematic longitudinal section through a sealing arrangement of the electrochemical unit 1 , along the line 3-3 in 1 ;

4 one of the 3 corresponding schematic longitudinal section through the sealing arrangement of the electrochemical unit in a second embodiment of the electrochemical unit, in which the electrochemical unit comprises a two-part bipolar plate and in the space between the two parts of the bipolar plate, a stabilizing element is arranged;

5 one of the 3 corresponding schematic longitudinal section through the sealing arrangement of the electrochemical unit in a third embodiment of the electrochemical unit, in which the bipartite bipolar plate in a connecting channel region of a flow field portion of the seal assembly has sufficient rigidity, so that to dispense with a support by support areas or a stabilizing element can; and

6 one of the 3 corresponding schematic longitudinal section through the sealing arrangement of the electrochemical unit, wherein the electrochemical unit comprises a bipartite bipolar plate and only one of the parts of the bipolar plate in a connection channel region of a flow field portion of the seal assembly has a greater height than in a longitudinal direction of the flow field section the sealing arrangement in front or behind the connecting channel area lying adjacent area.

Identical or functionally equivalent elements are denoted by the same reference numerals in all figures.

One in the 1 to 4 shown as a whole with 100 referred electrochemical device, such as a fuel cell stack or an electrolyzer, comprises a stack, the more in a stacking direction 104 successive electrochemical units 106 , For example, fuel cell units or electrolysis units, and a (not shown) clamping device for applying the electrochemical units with a along the stacking direction 104 includes directed clamping force.

How best of the 2 and 3 As can be seen, each electrochemical unit comprises 106 the electrochemical device 100 one bipolar plate each 108 and a membrane-electrode assembly (MEA) 110 ,

The membrane electrode assembly 110 includes, for example, a catalyst coated membrane (CCM) and two gas diffusion layers 112 and 114 , wherein a first gas diffusion layer 112 anode side and a second gas diffusion layer 114 is arranged on the cathode side.

The bipolar plate 108 is formed, for example, of a metallic material.

The bipolar plate 108 has several medium passage openings 116 on, through which each one of the electrochemical device 100 To be supplied fluid medium (in the case of a fuel cell stack, for example, a fuel gas, an oxidant or a coolant) through the bipolar plate 108 can pass through.

The medium passages 116 the stack of consecutive bipolar plates 108 and in the stacking direction 104 between the medium passage openings 116 lying intermediate spaces together form a medium channel 118 ,

Every medium channel 118 through which a fluid medium of the electrochemical device 100 can be supplied, in each case at least one other medium channel is assigned, through which the relevant fluid medium from the electrochemical device 100 is deductible.

Through an intermediate flow field 120 which is preferably on a surface of an adjacent bipolar plate 108 or (for example, in the case of a coolant flow field) in the space between the layers of a multilayer bipolar plate 108 is formed, the medium from the first medium channel 118 transverse, preferably substantially perpendicular, to the stacking direction 104 to flow to the second medium channel.

In 1 is for example a medium channel 122 for a coolant of the electrochemical device 100 and a medium channel 124 for a fuel gas of the electrochemical device 100 shown.

By a connecting channel 121 stands each medium channel 118 in fluid communication with the respective associated flow field 120 ,

Each bipolar plate 108 includes in the embodiment shown in the drawings a first part 126 and a second part 128 , along longitudinal connecting lines 130 , what a 1 are shown in broken lines, preferably cohesively, in particular by welding, for example by laser welding, fluid-tight are fixed together.

The two parts 126 and 128 the bipolar plate 108 especially as a first location 132 and a second location 134 the bipolar plate 108 be educated.

How out 1 can be seen, is the medium channel 122 for coolant via a connection channel 136 for coolant passing through a gap between the first part 126 and a second part 128 the bipolar plate 108 is formed, in fluid communication with a flow field for the coolant, which in the space between the first part 126 and the second part of the bipolar plate 128 is trained.

How out 2 can be seen, is the medium channel 124 for fuel gas via a connecting channel 142 for fuel gas in fluid communication with a flow field 144 for the fuel gas, which is between the first part 126 the bipolar plate 108 and the first gas diffusion layer 112 is trained.

The connection channel 142 includes a connection chamber 146 passing through a space between the first part 126 and the second part 128 the bipolar plate 108 is formed and above the medium channel 124 for fuel gas facing inlet openings 148 in fluid communication with the medium channel 124 and above the flow field 144 for the fuel gas facing passage openings 150 in fluid communication with the flow field 144 stands.

To guide the flow of media through the respective associated flow fields are the first part 126 and the second part 128 the bipolar plate 108 in the field of flow fields 120 with flow guide elements 152 provided, which may be formed, for example, in the form of raised beads.

In the area of the flow guide elements 152 Show the parts 126 respectively 128 the bipolar plate 108 in each case a height H _S1 or H _S2 , measured from a common reference plane 154 the bipolar plate 108 ,

The reference plane 154 is perpendicular to the stacking direction 104 aligned and runs through the contact surfaces 156 in which the two parts 126 and 128 the bipolar plate 108 abut each other.

The reference plane thus forms a central plane of the multipart bipolar plate 108 ,

An unwanted escape of the fluid media from the medium channels 118 and the flow fields 120 the electrochemical device 100 is through a seal arrangement 158 avoided, their sealing lines 160 in the top view of 1 are shown by dotted lines.

The seal arrangement 158 includes a flow field section 162 with the outer sealing line 160a and the inner sealing line 160b which is between the flow fields 120 on the one hand and the medium channels 118 on the other hand run and the connecting channels 121 cross, through which the flow fields 120 with the respective associated media channels 118 in fluid communication with each other.

Furthermore, the sealing arrangement comprises 158 Medium channel sections 164 with sealing lines 160c , which in each case one of the medium channels 118 surrounded at least in sections and the relevant medium channel 118 from an outer edge 166 the bipolar plate 108 separate.

The medium channel sections 164 the seal arrangement 158 each comprise a sealing element 168 which is between a first position 132 a bipolar plate 108 and a second location 134 one in the stacking direction 104 neighboring bipolar 108 ' is arranged and substantially parallel to an edge 170 a medium passage opening 116 of the relevant medium channel 118 extends. In the area of the medium channel sections 164 have the sealing elements 168 the seal arrangement 158 a height h _{M which is} substantially constant in its longitudinal direction.

The flow field section 162 the seal arrangement 158 preferably comprises two sealing elements 172a and 172b which is also between the first position 132 the bipolar plate 108 and the second location 134 the adjacent bipolar plate 108 ' are arranged.

Here is the first sealing element 172a preferably at the (for example anode-side) first gas diffusion layer 112 set and the second sealing element 172b preferably at the (for example cathode-side) second gas diffusion layer 114 the membrane-electrode assembly 110 established.

For example, it can be provided that the sealing elements 172a and 172b to the respective associated gas diffusion layer 112 respectively 114 molded or molded.

It can be provided that the first sealing element 172a for example in the area of the outer sealing line 160a both at the first location 132 the bipolar plate 108 as well as the second location 134 the adjacent bipolar plate 108 ' and in the area of the inner sealing line 160b at the first location 132 the bipolar plate 108 and on the second sealing element 172b abuts while the second sealing element 172b in the area of the inner sealing line 160b at the second position of the bipolar plate 108 ' and on the first sealing element 172a is applied.

The sealing elements 168 the medium channel sections 164 the seal arrangement 158 can be integral with the first sealing element 172a of the flow field section 162 the seal arrangement 158 be educated.

The seal arrangement 158 can thus be formed in two parts, with a first part 192 the seal arrangement 158 the first sealing element 172a of the flow field section 162 and the sealing elements 168 the medium channel sections 164 and preferably from the first gas diffusion layer 112 is worn and where a second part 194 the seal arrangement 158 the second sealing element 172b of the flow field section 162 and preferably from the second gas diffusion layer 114 worn.

Because the first location 132 and the second location 134 the bipolar plate 108 in the area of a connection channel 121 (outside of support areas 196 ) are spaced apart (see in particular the 2 and 3 ), have the sealing elements 172a . 172b in this area of the flow field section 162 the seal arrangement 158 an overall height h, which is less than the height h _{M of} a sealing element 168 in the medium channel section 164 the seal arrangement 158 , The total height h corresponds to the sum of the individual heights h1 and h2 of the sealing elements 172a respectively 172b ,

As in particular from the longitudinal section through the flow field section 162 the seal arrangement 158 in the area of the outer sealing line 160a in 3 can be seen, the height h1, h2 of the sealing elements varies 172a . 172b in the assembled state of the electrochemical device 100 along the longitudinal direction 174 the seal arrangement 158 so as to vary the spacing of the layers 132 . 134 the bipolar plate 108 from the reference plane 154 compensate.

How out 4 As can be seen, the flow field section includes 162 the seal arrangement 158 a connection channel area 176 in which the flow field section 162 the connection channel 121 (For example, the connection channel 142 for fuel gas).

In this connection channel area 176 have the sealing elements 172a and 172b an overall height h _V on.

The opposite outer sides 178 the first location 132 and the second location 134 the bipolar plate 108 point in the connection channel area 176 (outside the support areas 196 ) each have a distance H _V1 or H _V2 from the reference plane 154 which is greater than the thickness d of the position in question 132 . 134 ,

Further, the flow field section includes 162 the seal arrangement 158 in the longitudinal direction 174 in front of or behind the connection channel area 176 lying neighboring areas 180 the seal arrangement 158 in which the sealing elements 172a . 172b have the total height h _N , which is greater than the total height h _{V of} the sealing elements 172a . 172b in the connection channel area 176 ,

The distances H _N1 and H _{N2 of} the outsides 178 the first location 132 or the second layer 134 the bipolar plate 108 from the reference plane 154 correspond in the neighboring areas 180 the respective material thickness d of the first layer 132 or the second layer 134 the bipolar plate 108 , The distances H _N1 and H _N2 in the neighboring areas 180 are thus smaller than the distances H _V1 or H _V2 in the connection channel area 176 ,

Between the connection channel area 176 and in each case a neighboring area 180 is a transitional area 182 the seal arrangement 158 arranged in which the total height h _{U of} the sealing elements 172a . 172b , preferably continuously, in particular substantially linear, along the longitudinal direction 174 from the total height h _V at the edge of the connection channel area 176 up to the total height h _N on the edge of the adjacent neighboring area 180 increases.

The distances H _U1 and H _{U2 of} the outsides 178 the first location 132 or the second layer 134 the bipolar plate 108 from the reference plane 154 take in the transition areas 182 , starting from the values H _V1 and H _V2, respectively, at the edge of the connection channel area 176 , preferably continuously, in particular substantially linear, along the longitudinal direction 174 up to the values H _N1 and H _N2, respectively, at the edge of the neighboring area adjacent to each other 180 ,

In the transition areas 182 thus form the layers 132 and 134 the bipolar plate 108 opposite the reference plane 154 and opposite the stacking direction 104 inclined ramps 184 which the sealing elements 172a or 172b support.

The mean inclination angle α of the respective associated sealing element 172a . 172b facing outside 178 the first location 132 and / or the second layer 134 the bipolar plate 108 opposite the reference plane 154 is in the range of ramps 184 preferably at most about 45 °, in particular at most about 30 °, particularly preferably at most about 20 °.

The sum of the total height h of the respective sealing elements 172a . 172b and the distances H ₁ and H _{2 of} the respectively assigned position 132 respectively 134 the bipolar plate 108 from the reference plane 154 is in the flow field section 162 along the longitudinal direction 174 the seal arrangement 158 essentially constant (h _N + H _N1 + H _N2 = h _U + H _U1 + H _U2 = h _V + H _V1 + H _V2 ).

By this embodiment of the flow field section 162 the seal arrangement 158 On the one hand it is achieved that the layers 132 and 134 the bipolar plate 108 in the connection channel area 176 have a sufficient distance from each other to a sufficient fluid flow between the medium channel 118 and the flow field 120 through the connection channel 121 to ensure.

On the other hand it is achieved that outside the connection channel area 176 the height of the sealing elements 172a . 172b is as large as possible, so these sealing elements 172a . 172b There have the greatest possible elastic deformability and also large dynamic thickness variations in the operation of the electrochemical device 100 can compensate.

Furthermore, this configuration of the sealing arrangement 158 achieved that the sealing elements 172a . 172b from in the stacking direction 104 successive electrochemical units 106 in the flow field section 172 the seal arrangement 158 each other - along the stacking direction 104 Seen - at least partially and preferably completely overlap.

Preferably, the sealing elements 172a and 172b from in the stacking direction 104 successive electrochemical units 106 formed and arranged substantially congruent.

The total height h _{N of} the sealing elements 172a . 172b in the neighboring area 180 of the flow field section 162 the seal arrangement 158 may be substantially the same size as the height h _{M of} the sealing element 168 in the medium channel section 164 the seal arrangement 158 ,

In the in the 1 to 3 illustrated first embodiment of an electrochemical device 100 the distance between the two layers remains 132 and 134 the bipolar plate 108 which the connecting channel 121 limit, in the connection channel area 176 the seal arrangement 158 outside the support areas 196 even if the electrochemical units of the electrochemical device 100 in the stacking direction 104 be braced against each other because the layers 132 and 134 in the support areas 196 to project each other and to support surfaces 198 the support areas 196 touch and support each other.

The support areas 196 may be formed for example in the form of cups or webs.

The support areas 196 are preferably integral with one of the two layers to be supported 132 or 134 formed and preferably by a forming process, in particular a stamping or deep drawing process, at the respective position 132 or 134 educated.

That the connection channel 121 medium flowing through preferably flows laterally on the support areas 196 past.

The interiors 200 the support areas 196 are preferably outside the connection channel 121 ,

An in 4 illustrated second embodiment of an electrochemical device 100 is different from the one in the 1 to 3 illustrated embodiment in that the layers 132 and 134 the bipolar plate 108 in the area of the connection channel 121 no support areas 196 have and that in the space between the two layers 132 and 134 the bipolar plate 108 at least one stabilizing element 186 is arranged.

The stabilizing element 186 relies on one or more support points 188 at the first location 132 the bipolar plate 108 and at one or more support points 190 at the second location 134 the bipolar plate 108 from.

The stabilizing element 186 may have a wave-shaped cross section.

The stabilizing element 186 can as a separate from the layers 132 and 134 the bipolar plate 108 manufactured part be formed and in the preparation of the bipolar plate 108 in the space between the two layers 132 and 134 the bipolar plate 108 be inserted.

Alternatively, it can also be provided that the stabilizing element 186 in one piece with one of the two layers 132 . 134 the bipolar plate 108 is formed and by a forming process, for example by a folding process, in the manufacture of the bipolar plate 108 in the space between the two layers 132 and 134 the bipolar plate 108 is introduced.

The stabilizing element 186 gets the distance between the first layer 132 and the second location 134 the bipolar plate 108 in the connection channel area 176 even upright when the layers 132 . 134 the bipolar plate 108 be subjected to a clamping force which exceeds their inherent stability.

Incidentally, the in 4 illustrated second embodiment of an electrochemical device in terms of structure, function and method of manufacture with in the 1 to 3 to the first embodiment described, the above description of which reference is made.

At the in 5 illustrated third embodiment of an electrochemical device 100 the distance between the two layers remains 132 and 134 the bipolar plate 108 which the connecting channel 121 limit, in the connection channel area 176 the seal arrangement 158 because of the inherent stability of these layers 132 . 134 also obtained when the electrochemical units 106 the electrochemical device 100 in the stacking direction 104 be braced against each other, so that in this embodiment, a stabilizing element 186 and into the bipolar plate 108 integrated support areas 196 can be waived.

An in 6 illustrated fourth embodiment of an electrochemical device 100 is different from the one in 5 illustrated third embodiment in that in the flow field section 162 the seal arrangement 158 only the distance H ₁ or H _{2 of} one of the layers 132 . 134 the bipolar plate 108 , For example, the distance H _{1 of} the first layer 132 , from the reference plane 154 in the longitudinal direction 174 the seal arrangement 158 varies, as has been described above in connection with the first embodiment.

The other situation 132 . 134 the bipolar plate 108 So for example the second layer 134 , in this embodiment, however, is in the flow field section 162 formed substantially flat, so that the distance H _{2 of} the outside 178 the second location 134 the bipolar plate 108 from the reference plane 154 in the flow field section 162 is substantially the same size everywhere as the material thickness d of the second layer 134 ,

To adapt to this shape of the second layer 134 the bipolar plate 108 also has the same associated second sealing element 172b in the flow field section 162 everywhere substantially the same height h ', which in particular the height h _{N of} the second sealing element 172b in the neighboring areas 180 in the first embodiment (see 3 ).

Incidentally, the in 6 illustrated fourth embodiment of an electrochemical device 100 in terms of structure, function and method of production with in the 1 to 3 illustrated in the first embodiment, reference is made to the above description in this regard.

In variants of the embodiments described above, it could be provided that the total height h of the sealing elements 172a . 172b in the different areas of the flow field section 162 the seal arrangement 158 , especially in the connection channel area 176 and in the neighboring areas 180 , varies, especially because in the area of the connection channel area 176 a not quite flat, for example, corrugated, sealing surface is present.

In this case, for h _V and h _N, those over the respective range, ie in particular via the connection channel area 176 or one of the neighboring areas 180 to set averaged values. The same applies to the distances H ₁ and H _{2 of} the outsides 178 the layers 132 . 134 the bipolar plate 108 from the reference plane 154 ,

Claims (16)

Electrochemical device comprising a stack of several, along a stacking direction ( 104 ) successive electrochemical units ( 106 ), each having an electrochemically active membrane electrode assembly ( 110 ), a bipolar plate ( 108 ) and at least one sealing element ( 172a . 172b ), at least one medium channel ( 118 ) extending along the stacking direction ( 104 ) through several of the electrochemical units ( 106 ), at least one flow field ( 120 ) through which a medium from the medium channel ( 118 ) transverse to the stacking direction ( 104 ) from the medium channel ( 118 ) to another medium channel ( 118 ) and at least one communication channel ( 121 ), through which the flow field ( 120 ) and the medium channel ( 118 ) are in fluid communication with each other, the sealing arrangement ( 158 ) a connection channel area ( 176 ), in which the sealing arrangement ( 158 ) the at least one connection channel ( 121 ), and at least one in the longitudinal direction ( 174 ) of the sealing arrangement ( 158 ) in front of or behind the connection channel area ( 176 ) neighboring area ( 180 ), wherein the sealing arrangement ( 158 ) in the connection channel area ( 176 ) has a lower average height (h) than in the neighboring area ( 180 ). Electrochemical device according to claim 1, characterized in that between the connecting channel region ( 176 ) and the neighboring area ( 180 ) a transition area ( 182 ) is arranged, in which the height (h) of the sealing arrangement ( 158 ) from the neighboring area ( 180 ) proceeding to the connection channel area ( 176 ) decreases. Electrochemical device according to one of claims 1 or 2, characterized in that at least one sealing element ( 172a . 172b ) of the sealing arrangement ( 158 ) in the connection channel area ( 176 ) and in the neighboring area ( 180 ) with the bipolar plate ( 108 ), wherein the average distance (H) of a sealing element ( 172a . 172b ) facing outside ( 178 ) of the bipolar plate ( 108 ) from a direction perpendicular to the stacking direction ( 104 ) reference plane ( 154 ) of the bipolar plate ( 108 ) in the connection channel area ( 176 ) is larger than in the neighboring area ( 180 ). Electrochemical device according to claim 3, characterized in that the sealing element ( 172a . 172b ) facing outside ( 178 ) of the bipolar plate ( 108 ) in one between the connection channel area ( 176 ) and the neighboring area ( 180 ) transition region ( 182 ) relative to the reference plane ( 154 ) of the bipolar plate ( 108 ) is inclined. Electrochemical device according to claim 4, characterized in that the average angle of inclination (α) of the sealing element ( 172a . 172b ) facing outside ( 178 ) of the bipolar plate ( 108 ) relative to the reference plane ( 154 ) in the transition area ( 182 ) is at most about 45 °. Electrochemical device according to one of claims 3 to 5, characterized in that the sum of the average height (h) of the sealing arrangement ( 158 ) and the mean distances (H ₁ , H ₂ ) of the reference plane ( 154 ) facing away from outside ( 178 ) of the bipolar plate ( 108 ) from the reference plane ( 154 ) in the connection channel area ( 176 ) and in the neighboring area ( 180 ) is substantially the same size. Electrochemical device according to one of Claims 3 to 6, characterized in that at least one of the electrochemical units ( 106 ) a sealing arrangement ( 158 ) with two sealing elements ( 172a . 172b ), which together form a distance between the bipolar plate ( 108 ) of the electrochemical unit ( 106 ) and a bipolar plate ( 108 ' ) of an adjacent electrochemical unit ( 106 ) along the stacking direction ( 104 ) bridge. Electrochemical device according to claim 7, characterized in that the sealing elements ( 172a . 172b ) are formed and arranged such that they - along the stacking direction ( 104 ) - at least partially overlapping each other. Electrochemical device according to one of Claims 1 to 8, characterized in that the bipolar plate ( 108 ) two parts ( 126 . 128 ), which in the connection channel area ( 176 ) are at least partially spaced from each other. Electrochemical device according to claim 9, characterized in that the mean distance (H ₁ , H ₂ ) of the reference plane ( 154 ) of the bipolar plate ( 108 ) facing away from outside ( 178 ) of the bipolar plate ( 108 ) from the reference plane ( 154 ) of the bipolar plate ( 108 ) in both parts ( 126 . 128 ) of the bipolar plate ( 108 ) in the connection channel area ( 176 ) is larger than in the neighboring area ( 180 ). Electrochemical device according to claim 9, characterized in that the mean distance (H ₁ , H ₂ ) of the reference plane ( 154 ) of the bipolar plate ( 108 ) facing away from outside ( 178 ) of the bipolar plate ( 108 ) from the reference plane ( 154 ) of the bipolar plate ( 108 ) at one of the parts ( 126 . 128 ) of the bipolar plate ( 108 ) in the connection channel area ( 176 ) is substantially the same size as in the neighboring area ( 180 ). Electrochemical device according to one of Claims 9 to 11, characterized in that at least one of the parts ( 126 . 128 ) of the bipolar plate ( 108 ) with one or more support areas ( 196 ), with which this part ( 126 . 128 ) of the bipolar plate in the connection channel region ( 176 ) at the other part ( 128 . 126 ) is supported. Electrochemical device according to one of claims 9 to 12, characterized in that in the space between the two parts ( 126 . 128 ) of the bipolar plate ( 108 ) at least one stabilizing element ( 186 ) is arranged. Electrochemical device according to claim 13, characterized in that the stabilizing element ( 186 ) in one piece with one of the parts ( 126 . 128 ) of the bipolar plate ( 108 ) is trained. Electrochemical device according to one of claims 1 to 14, characterized in that at least one sealing element ( 172a . 172b ) of the sealing arrangement ( 158 ) on the membrane electrolyte assembly ( 110 ) of the respective electrochemical unit ( 106 ). Electrochemical device according to one of claims 1 to 15, characterized in that at least one sealing element ( 172a . 172b ) of the sealing arrangement ( 158 ) comprises an elastomeric material.

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